langchain/libs/partners/mongodb/langchain_mongodb/utils.py

"""
Tools for the Maximal Marginal Relevance (MMR) reranking.
Duplicated from langchain_community to avoid cross-dependencies.

Functions "maximal_marginal_relevance" and "cosine_similarity"
are duplicated in this utility respectively from modules:
    - "libs/community/langchain_community/vectorstores/utils.py"
    - "libs/community/langchain_community/utils/math.py"
"""

import logging
from typing import List, Union

import numpy as np

logger = logging.getLogger(__name__)

Matrix = Union[List[List[float]], List[np.ndarray], np.ndarray]


def cosine_similarity(X: Matrix, Y: Matrix) -> np.ndarray:
    """Row-wise cosine similarity between two equal-width matrices."""
    if len(X) == 0 or len(Y) == 0:
        return np.array([])

    X = np.array(X)
    Y = np.array(Y)
    if X.shape[1] != Y.shape[1]:
        raise ValueError(
            f"Number of columns in X and Y must be the same. X has shape {X.shape} "
            f"and Y has shape {Y.shape}."
        )
    try:
        import simsimd as simd  # type: ignore

        X = np.array(X, dtype=np.float32)
        Y = np.array(Y, dtype=np.float32)
        Z = 1 - simd.cdist(X, Y, metric="cosine")
        if isinstance(Z, float):
            return np.array([Z])
        return Z
    except ImportError:
        logger.info(
            "Unable to import simsimd, defaulting to NumPy implementation. If you want "
            "to use simsimd please install with `pip install simsimd`."
        )
        X_norm = np.linalg.norm(X, axis=1)
        Y_norm = np.linalg.norm(Y, axis=1)
        # Ignore divide by zero errors run time warnings as those are handled below.
        with np.errstate(divide="ignore", invalid="ignore"):
            similarity = np.dot(X, Y.T) / np.outer(X_norm, Y_norm)
        similarity[np.isnan(similarity) | np.isinf(similarity)] = 0.0
        return similarity


def maximal_marginal_relevance(
    query_embedding: np.ndarray,
    embedding_list: list,
    lambda_mult: float = 0.5,
    k: int = 4,
) -> List[int]:
    """Calculate maximal marginal relevance."""
    if min(k, len(embedding_list)) <= 0:
        return []
    if query_embedding.ndim == 1:
        query_embedding = np.expand_dims(query_embedding, axis=0)
    similarity_to_query = cosine_similarity(query_embedding, embedding_list)[0]
    most_similar = int(np.argmax(similarity_to_query))
    idxs = [most_similar]
    selected = np.array([embedding_list[most_similar]])
    while len(idxs) < min(k, len(embedding_list)):
        best_score = -np.inf
        idx_to_add = -1
        similarity_to_selected = cosine_similarity(embedding_list, selected)
        for i, query_score in enumerate(similarity_to_query):
            if i in idxs:
                continue
            redundant_score = max(similarity_to_selected[i])
            equation_score = (
                lambda_mult * query_score - (1 - lambda_mult) * redundant_score
            )
            if equation_score > best_score:
                best_score = equation_score
                idx_to_add = i
        idxs.append(idx_to_add)
        selected = np.append(selected, [embedding_list[idx_to_add]], axis=0)
    return idxs
mongodb[minor]: MongoDB Partner Package -- Porting MongoDBAtlasVectorSearch (#17652) This PR migrates the existing MongoDBAtlasVectorSearch abstraction from the `langchain_community` section to the partners package section of the codebase. - [x] Run the partner package script as advised in the partner-packages documentation. - [x] Add Unit Tests - [x] Migrate Integration Tests - [x] Refactor `MongoDBAtlasVectorStore` (autogenerated) to `MongoDBAtlasVectorSearch` - [x] ~Remove~ deprecate the old `langchain_community` VectorStore references. ## Additional Callouts - Implemented the `delete` method - Included any missing async function implementations - `amax_marginal_relevance_search_by_vector` - `adelete` - Added new Unit Tests that test for functionality of `MongoDBVectorSearch` methods - Removed [`del res[self._embedding_key]`](https://github.com/langchain-ai/langchain/blob/e0c81e1cb0ede673a69aae6434e17e34868c3bcc/libs/community/langchain_community/vectorstores/mongodb_atlas.py#L218) in `_similarity_search_with_score` function as it would make the `maximal_marginal_relevance` function fail otherwise. The `Document` needs to store the embedding key in metadata to work. Checklist: - [x] PR title: Please title your PR "package: description", where "package" is whichever of langchain, community, core, experimental, etc. is being modified. Use "docs: ..." for purely docs changes, "templates: ..." for template changes, "infra: ..." for CI changes. - Example: "community: add foobar LLM" - [x] PR message - [x] Pass lint and test: Run `make format`, `make lint` and `make test` from the root of the package(s) you've modified to check that you're passing lint and testing. See contribution guidelines for more information on how to write/run tests, lint, etc: https://python.langchain.com/docs/contributing/ - [x] Add tests and docs: If you're adding a new integration, please include 1. Existing tests supplied in docs/docs do not change. Updated docstrings for new functions like `delete` 2. an example notebook showing its use. It lives in `docs/docs/integrations` directory. (This already exists) If no one reviews your PR within a few days, please @-mention one of baskaryan, efriis, eyurtsev, hwchase17. --------- Co-authored-by: Steven Silvester <steven.silvester@ieee.org> Co-authored-by: Erick Friis <erick@langchain.dev> 2024-02-29 23:09:48 +00:00			`"""`
			`Tools for the Maximal Marginal Relevance (MMR) reranking.`
			`Duplicated from langchain_community to avoid cross-dependencies.`

			`Functions "maximal_marginal_relevance" and "cosine_similarity"`
			`are duplicated in this utility respectively from modules:`
			`- "libs/community/langchain_community/vectorstores/utils.py"`
			`- "libs/community/langchain_community/utils/math.py"`
			`"""`

			`import logging`
			`from typing import List, Union`

			`import numpy as np`

			`logger = logging.getLogger(__name__)`

			`Matrix = Union[List[List[float]], List[np.ndarray], np.ndarray]`


			`def cosine_similarity(X: Matrix, Y: Matrix) -> np.ndarray:`
			`"""Row-wise cosine similarity between two equal-width matrices."""`
			`if len(X) == 0 or len(Y) == 0:`
			`return np.array([])`

			`X = np.array(X)`
			`Y = np.array(Y)`
			`if X.shape[1] != Y.shape[1]:`
			`raise ValueError(`
			`f"Number of columns in X and Y must be the same. X has shape {X.shape} "`
			`f"and Y has shape {Y.shape}."`
			`)`
			`try:`
			`import simsimd as simd # type: ignore`

			`X = np.array(X, dtype=np.float32)`
			`Y = np.array(Y, dtype=np.float32)`
			`Z = 1 - simd.cdist(X, Y, metric="cosine")`
			`if isinstance(Z, float):`
			`return np.array([Z])`
			`return Z`
			`except ImportError:`
			`logger.info(`
			`"Unable to import simsimd, defaulting to NumPy implementation. If you want "`
			"to use simsimd please install with `pip install simsimd`."
			`)`
			`X_norm = np.linalg.norm(X, axis=1)`
			`Y_norm = np.linalg.norm(Y, axis=1)`
			`# Ignore divide by zero errors run time warnings as those are handled below.`
			`with np.errstate(divide="ignore", invalid="ignore"):`
			`similarity = np.dot(X, Y.T) / np.outer(X_norm, Y_norm)`
			`similarity[np.isnan(similarity) \| np.isinf(similarity)] = 0.0`
			`return similarity`


			`def maximal_marginal_relevance(`
			`query_embedding: np.ndarray,`
			`embedding_list: list,`
			`lambda_mult: float = 0.5,`
			`k: int = 4,`
			`) -> List[int]:`
			`"""Calculate maximal marginal relevance."""`
			`if min(k, len(embedding_list)) <= 0:`
			`return []`
			`if query_embedding.ndim == 1:`
			`query_embedding = np.expand_dims(query_embedding, axis=0)`
			`similarity_to_query = cosine_similarity(query_embedding, embedding_list)[0]`
			`most_similar = int(np.argmax(similarity_to_query))`
			`idxs = [most_similar]`
			`selected = np.array([embedding_list[most_similar]])`
			`while len(idxs) < min(k, len(embedding_list)):`
			`best_score = -np.inf`
			`idx_to_add = -1`
			`similarity_to_selected = cosine_similarity(embedding_list, selected)`
			`for i, query_score in enumerate(similarity_to_query):`
			`if i in idxs:`
			`continue`
			`redundant_score = max(similarity_to_selected[i])`
			`equation_score = (`
			`lambda_mult * query_score - (1 - lambda_mult) * redundant_score`
			`)`
			`if equation_score > best_score:`
			`best_score = equation_score`
			`idx_to_add = i`
			`idxs.append(idx_to_add)`
			`selected = np.append(selected, [embedding_list[idx_to_add]], axis=0)`
			`return idxs`